aaa
This commit is contained in:
54
按方法整理/常微分方程-阿达姆斯方法.py
Normal file
54
按方法整理/常微分方程-阿达姆斯方法.py
Normal file
@@ -0,0 +1,54 @@
|
||||
import math
|
||||
|
||||
|
||||
def AdamusExplicitly(k,first_ys,x0,y0,h,xk,fxy,fx_real):
|
||||
betas = [
|
||||
[1],
|
||||
[3/2, -1/2],
|
||||
[23/12, -16/12, 5/12],
|
||||
[55/24, -59/24, 37/24, -9/24],
|
||||
[1901/720, -2774/720, 2626/720, -1274/720, 251/720],
|
||||
[4277/1440, -7923/1600, 9982/1440, -7298/1440, 2877/1440, -476/1440]
|
||||
]
|
||||
# Bks = [1/2,5/12,3/8,251/720,95/288,10987/60480]
|
||||
result = []
|
||||
if k<0 or k >= len(betas):
|
||||
print("k超出范围")
|
||||
return None
|
||||
if len(first_ys) != k + 1:
|
||||
print("first_ys(前几个y的值)与k长度不匹配")
|
||||
return None
|
||||
fxys = [fxy(x0+i*h, first_ys[i]) for i in range(k + 1)]
|
||||
for i in range(k + 1):
|
||||
result.append((x0 + i * h, first_ys[i]))
|
||||
x1 = x0 + h*k
|
||||
y0 = first_ys[k]
|
||||
while x1 < xk:
|
||||
x1 += h
|
||||
delta_y = h * sum(betas[k][i] * fxys[k-i] for i in range(k + 1))
|
||||
y1 = y0 + delta_y
|
||||
print(f"x={x1}, y={y1}, delta_y={delta_y}, real_y={fx_real(x1)}, abs(real_y-y)={abs(fx_real(x1) - y1)}")
|
||||
result.append((x1, y1))
|
||||
fxys.append(fxy(x1, y1))
|
||||
fxys.pop(0)
|
||||
y0 = y1
|
||||
return result
|
||||
|
||||
|
||||
|
||||
if __name__ == "__main__":
|
||||
# 定义初始值和参数#####################################################################################
|
||||
k = 3 # 阿达姆斯k+1步显式方法,精度为k+1阶,最常用k=3,其他阶数我没试过 P253
|
||||
first_ys = [1, 0.904837418036, 0.818730753078, 0.7408182206817] # 前几个y的值,可用龙格-库塔计算或者知道精确解自己算出来
|
||||
x0 = 0.0 # 初始x值
|
||||
y0 = 1.0 # 初始y值
|
||||
h = 0.1 # 步长
|
||||
xk = 1.0 # 最终x值
|
||||
fxy = lambda x, y: -y # 定义f(x,y)函数,dx/dy = f(x,y),导函数
|
||||
fx_real = lambda x: math.exp(-x) # 实际解函数,用于验证结果,如果不知道或者不用算误差,可以直接写个 lambda x: 0
|
||||
# 调用阿达姆斯显式方法
|
||||
result = AdamusExplicitly(k, first_ys, x0, y0, h, xk, fxy, fx_real)
|
||||
print("计算结果看到有几.99999或者几.00000就自己四舍五入一下,有可能会多算一点,自己比较一下")
|
||||
if result:
|
||||
for xy in result:
|
||||
print(f"(x, y): {xy}")
|
||||
65
按方法整理/常微分方程-阿达姆斯预测-校正方法.py
Normal file
65
按方法整理/常微分方程-阿达姆斯预测-校正方法.py
Normal file
@@ -0,0 +1,65 @@
|
||||
import math
|
||||
|
||||
|
||||
def AdamusFix(k,first_ys,x0,y0,h,xk,fxy,fx_real):
|
||||
betas_1 = [
|
||||
[1],
|
||||
[3/2, -1/2],
|
||||
[23/12, -16/12, 5/12],
|
||||
[55/24, -59/24, 37/24, -9/24],
|
||||
[1901/720, -2774/720, 2626/720, -1274/720, 251/720],
|
||||
[4277/1440, -7923/1600, 9982/1440, -7298/1440, 2877/1440, -476/1440]
|
||||
]
|
||||
# Bks = [1/2,5/12,3/8,251/720,95/288,10987/60480]
|
||||
betas_2 = [
|
||||
[1],
|
||||
[1/2, 1/2],
|
||||
[5/12, 8/12, -1/12],
|
||||
[9/24, 19/24, -5/24, 1/24],
|
||||
[251/720, 646/720, -261/720, 106/720, -19/720],
|
||||
[475/1440, 1427/1440, -798/1440, 482/1440, -173/1440, 27/1440]
|
||||
]
|
||||
result = []
|
||||
if k<0 or k >= len(betas_1):
|
||||
print("k超出范围")
|
||||
return None
|
||||
if len(first_ys) != k + 1:
|
||||
print("first_ys(前几个y的值)与k长度不匹配")
|
||||
return None
|
||||
fxys = [fxy(x0+i*h, first_ys[i]) for i in range(k + 1)]
|
||||
for i in range(k + 1):
|
||||
result.append((x0 + i * h, first_ys[i]))
|
||||
x1 = x0 + h*k
|
||||
y0 = first_ys[k]
|
||||
while x1 < xk:
|
||||
x1 += h
|
||||
y1_guess = y0 + h * sum(betas_1[k][i] * fxys[k-i] for i in range(k + 1))
|
||||
fxy_guess = fxy(x1, y1_guess)
|
||||
fxys.append(fxy_guess)
|
||||
fxys.pop(0)
|
||||
delta_y = h * sum(betas_2[k][i] * fxys[k-i] for i in range(k + 1))
|
||||
y1 = y0 + delta_y
|
||||
print(f"x={x1}, y={y1}, y_guess={y1_guess}, real_y={fx_real(x1)}, abs(real_y-y)={abs(fx_real(x1) - y1)}")
|
||||
result.append((x1, y1))
|
||||
fxys[k] = fxy(x1, y1)
|
||||
y0 = y1
|
||||
return result
|
||||
|
||||
|
||||
|
||||
if __name__ == "__main__":
|
||||
# 定义初始值和参数#####################################################################################
|
||||
k = 3 # 阿达姆斯k+1步显式方法,精度为k+1阶,最常用k=3,其他阶数我没试过 P253
|
||||
first_ys = [1, 1.0954, 1.1832, 1.2649] # 前几个y的值,可用龙格-库塔计算或者知道精确解自己算出来
|
||||
x0 = 0.0 # 初始x值
|
||||
y0 = 1.0 # 初始y值
|
||||
h = 0.1 # 步长
|
||||
xk = 1.0 # 最终x值
|
||||
fxy = lambda x, y: y - 2*x/y # 定义f(x,y)函数,dx/dy = f(x,y),导函数
|
||||
fx_real = lambda x: 0 # 实际解函数,用于验证结果,如果不知道或者不用算误差,可以直接写个 lambda x: 0
|
||||
# 调用阿达姆斯显式方法
|
||||
result = AdamusFix(k, first_ys, x0, y0, h, xk, fxy, fx_real)
|
||||
print("计算结果看到有几.99999或者几.00000就自己四舍五入一下,有可能会多算一点,自己比较一下")
|
||||
if result:
|
||||
for xy in result:
|
||||
print(f"(x, y): {xy}")
|
||||
133
按方法整理/拟合-最小二乘法.py
Normal file
133
按方法整理/拟合-最小二乘法.py
Normal file
@@ -0,0 +1,133 @@
|
||||
import math
|
||||
|
||||
# 列主元高斯消元法
|
||||
def SovleRowMain(A,b):
|
||||
ks = 0.00000001
|
||||
n = len(A)
|
||||
if len(A[0]) != n:
|
||||
print("A要为方阵")
|
||||
return None,None,None,None
|
||||
if len(b) != n:
|
||||
print("b与A的行数不匹配")
|
||||
return None,None,None,None
|
||||
p = list(range(n))
|
||||
for i in range(n):
|
||||
row_max = abs(A[i][i])
|
||||
row_max_index = i
|
||||
for j in range(i + 1, n):
|
||||
if abs(A[j][i]) > row_max:
|
||||
row_max = abs(A[j][i])
|
||||
row_max_index = j
|
||||
A[i], A[row_max_index] = A[row_max_index], A[i]
|
||||
b[i], b[row_max_index] = b[row_max_index], b[i]
|
||||
p[i], p[row_max_index] = p[row_max_index], p[i]
|
||||
|
||||
if abs(A[i][i]) < ks:
|
||||
print("A矩阵奇异,无法进行高斯消元")
|
||||
return None,None,None,None
|
||||
for j in range(i + 1, n):
|
||||
m = A[j][i] / A[i][i]
|
||||
A[j][i] = m
|
||||
for k in range(i + 1, n):
|
||||
A[j][k] -= m * A[i][k]
|
||||
b[j] -= m * b[i]
|
||||
|
||||
if abs(A[n - 1][n - 1]) < ks:
|
||||
print("A矩阵奇异,无法进行高斯消元")
|
||||
return None,None,None,None
|
||||
|
||||
# 回代求解
|
||||
b[n - 1] /= A[n - 1][n - 1]
|
||||
for i in range(n - 2, -1, -1):
|
||||
for j in range(i + 1, n):
|
||||
b[i] -= A[i][j] * b[j]
|
||||
b[i] /= A[i][i]
|
||||
return b
|
||||
|
||||
|
||||
# 最小二乘法拟合
|
||||
def LeastSquares(list_x,list_y,n):
|
||||
m = len(list_x)
|
||||
x_n = []
|
||||
b = []
|
||||
for i in range(2*n+1):
|
||||
x_n.append(0)
|
||||
b.append(0)
|
||||
for j in range(m):
|
||||
x_n[i]+=(list_x[j]**i)
|
||||
b[i]+=(list_y[j]*list_x[j]**i)
|
||||
b = b[:n+1]
|
||||
A = []
|
||||
for i in range(n+1):
|
||||
tmp = []
|
||||
for j in range(n+1):
|
||||
tmp.append(x_n[i+j])
|
||||
A.append(tmp)
|
||||
print("A:", A)
|
||||
print("b:", b)
|
||||
result = SovleRowMain(A, b)
|
||||
print("result:", result)
|
||||
return result
|
||||
|
||||
# 计算多项式在给定x值上的值
|
||||
def CalculateY(list_x, coeff):
|
||||
re = []
|
||||
for i in range(len(list_x)):
|
||||
re.append(0)
|
||||
for j in range(len(coeff)):
|
||||
re[i] += coeff[j]*list_x[i]**j
|
||||
return re
|
||||
|
||||
# 计算均方根误差
|
||||
def MeanSquareErr(list_y,list_y_approx):
|
||||
m = len(list_y)
|
||||
err = 0
|
||||
for i in range(m):
|
||||
err += (list_y[i] - list_y_approx[i])**2
|
||||
return err**0.5
|
||||
|
||||
# 计算最大误差
|
||||
def MaxErr(list_y,list_y_approx):
|
||||
m = len(list_y)
|
||||
err = 0
|
||||
for i in range(m):
|
||||
if abs(list_y[i] - list_y_approx[i]) > err:
|
||||
err = abs(list_y[i] - list_y_approx[i])
|
||||
return err
|
||||
|
||||
# 打印拟合方程
|
||||
def PrintEquation(coeff):
|
||||
n = len(coeff)
|
||||
str_ = str(coeff[0]) + "+"
|
||||
for i in range(0,n-1):
|
||||
str_ += str(coeff[i+1])
|
||||
str_ += "*x^"+str(i+1)+"+"
|
||||
str_ = str_[0:len(str_)-1]
|
||||
print(str_)
|
||||
|
||||
|
||||
if __name__ == "__main__":
|
||||
##########################################################################
|
||||
# 下面的数值根据题意改成适合的,比如要取对数就先取对数,下面的x和y是直接用于拟合的
|
||||
list_x = [2,4,6,8] # 已给出的x数值,与y数值对应
|
||||
list_y = [2,11,28,40] # 已给出的y数值,与x数值对应
|
||||
|
||||
# 记得改下面最后一个参数,为拟合阶数
|
||||
print("一次拟合")
|
||||
coeff = LeastSquares(list_x,list_y,1)
|
||||
PrintEquation(coeff)
|
||||
y_approx = CalculateY(list_x, coeff)
|
||||
print("均方根误差:")
|
||||
print(MeanSquareErr(list_y,y_approx))
|
||||
print("最大误差:")
|
||||
print(MaxErr(list_y,y_approx))
|
||||
|
||||
print("二次拟合")
|
||||
coeff = LeastSquares(list_x,list_y,2)
|
||||
PrintEquation(coeff)
|
||||
y_approx = CalculateY(list_x, coeff)
|
||||
print("均方根误差:")
|
||||
print(MeanSquareErr(list_y,y_approx))
|
||||
print("最大误差:")
|
||||
print(MaxErr(list_y,y_approx))
|
||||
|
||||
122
按方法整理/插值-三次样条.py
Normal file
122
按方法整理/插值-三次样条.py
Normal file
@@ -0,0 +1,122 @@
|
||||
import math
|
||||
|
||||
# 追赶法
|
||||
def ZGsolve(A,b):
|
||||
n = len(b)
|
||||
beta = [0]*n
|
||||
for i in range(n):
|
||||
if i == 0:
|
||||
beta[i] = A[i][2] / A[i][1]
|
||||
else:
|
||||
beta[i] = A[i][2] / (A[i][1] - A[i][0]*beta[i-1])
|
||||
|
||||
for i in range(n):
|
||||
if i == 0:
|
||||
b[i] = b[i] / A[i][1]
|
||||
else:
|
||||
b[i] = (b[i] - A[i][0]*b[i-1]) / (A[i][1] - A[i][0]*beta[i-1])
|
||||
|
||||
for i in range(n-2,-1,-1):
|
||||
b[i] = b[i] - beta[i]*b[i+1]
|
||||
|
||||
return b
|
||||
|
||||
# 获取相邻点的差分
|
||||
def GetDList(list_r):
|
||||
result = []
|
||||
for i in range(1,len(list_r)):
|
||||
result.append(list_r[i] - list_r[i-1])
|
||||
return result
|
||||
|
||||
# 获取相邻点的差商
|
||||
def GetDQList(list_x, list_y):
|
||||
result = []
|
||||
for i in range(1,len(list_y)):
|
||||
result.append((list_y[i] - list_y[i-1]) / (list_x[i] - list_x[i-1]))
|
||||
return result
|
||||
|
||||
# 三次样条插值
|
||||
def CubicSplineInterpolation(list_x,list_y,boundary_type,a1,a2):
|
||||
list_h = GetDList(list_x)
|
||||
print("h:", list_h)
|
||||
list_dqxy = GetDQList(list_x, list_y)
|
||||
print("f[xi,xi+1]:", list_dqxy)
|
||||
list_mu = [list_h[i]/(list_h[i]+list_h[i+1]) for i in range(len(list_h)-1)]
|
||||
print("miu:", list_mu)
|
||||
list_lamda = [1-i for i in list_mu]
|
||||
print("lambda:", list_lamda)
|
||||
list_g = [6*(list_dqxy[i+1]-list_dqxy[i])/(list_h[i+1]+list_h[i]) for i in range(len(list_h)-1)]
|
||||
A = []
|
||||
b = []
|
||||
M = []
|
||||
copy_b = []
|
||||
if boundary_type == 0: # 自然边界条件
|
||||
a1 = 0
|
||||
a2 = 0
|
||||
A.append([0,2,list_lamda[0]])
|
||||
b.append(list_g[0]-list_mu[0]*a1)
|
||||
for i in range(1,len(list_g)-1):
|
||||
A.append([list_mu[i],2,list_lamda[i]])
|
||||
b.append(list_g[i])
|
||||
A.append([list_mu[-1],2,0])
|
||||
b.append(list_g[-1]-list_lamda[-1]*a2)
|
||||
copy_b = b.copy()
|
||||
print("g1~gn-1:", list_g)
|
||||
M = ZGsolve(A,b)
|
||||
M = [a1] + M + [a2]
|
||||
elif boundary_type == 1: # 一阶导数边界条件
|
||||
A.append([0,2,1])
|
||||
b.append(6/list_h[0]*(list_dqxy[1]-a1))
|
||||
for i in range(len(list_g)):
|
||||
A.append([list_mu[i],2,list_lamda[i]])
|
||||
b.append(list_g[i])
|
||||
A.append([1,2,0])
|
||||
b.append(6/list_h[-1]*(a2-list_dqxy[-1]))
|
||||
copy_b = b.copy()
|
||||
print("g0~gn:", copy_b)
|
||||
|
||||
M = ZGsolve(A,b)
|
||||
|
||||
elif boundary_type == 2: # 二阶导数边界条件
|
||||
A.append([0,2,list_lamda[0]])
|
||||
b.append(list_g[0]-list_mu[0]*a1)
|
||||
for i in range(1,len(list_g)-1):
|
||||
A.append([list_mu[i],2,list_lamda[i]])
|
||||
b.append(list_g[i])
|
||||
A.append([list_mu[-1],2,0])
|
||||
b.append(list_g[-1]-list_lamda[-1]*a2)
|
||||
copy_b = b.copy()
|
||||
print("g1~gn-1:", list_g)
|
||||
M = ZGsolve(A,b)
|
||||
M = [a1] + M + [a2]
|
||||
print("A:", A)
|
||||
print("b:", copy_b)
|
||||
print("M:", M)
|
||||
return M,list_h
|
||||
|
||||
# 打印矩阵
|
||||
def PrintResult(M,list_h,list_x,list_y):
|
||||
for i in range(len(list_h)):
|
||||
k1 = (M[i+1]-M[i])/6/list_h[i]
|
||||
k2 = (M[i]*list_x[i+1]-M[i+1]*list_x[i])/2/list_h[i]
|
||||
k3 = (3*M[i+1]*list_x[i]**2-3*M[i]*list_x[i+1]**2-6*list_y[i]+M[i]*list_h[i]**2+6*list_y[i+1]-M[i+1]*list_h[i]**2)/6/list_h[i]
|
||||
k4 = (M[i]*list_x[i+1]**3-M[i+1]*list_x[i]**3+6*list_y[i]*list_x[i+1]-M[i]*list_h[i]**2*list_x[i+1]-6*list_y[i+1]*list_x[i]+M[i+1]*list_h[i]**2*list_x[i])/6/list_h[i]
|
||||
print("S(x)=%.6f*x^3+%.6f*x^2+%6f*x+%6f"%(k1,k2,k3,k4),"x=[%.6f,%.6f]"%(list_x[i],list_x[i+1]))
|
||||
|
||||
|
||||
if __name__ == "__main__":
|
||||
##############################################################################################################
|
||||
list_x = [0,1,2,3] # 已给出的x数值,与y数值对应
|
||||
list_y = [0,0,0,0] # 已给出的y数值,与x数值对应
|
||||
# 记得改后三个参数,分别为边界条件类型(0=自然边界条件,1=一阶导数边界条件,2=二阶导数边界条件),边界条件a1和a2
|
||||
M,list_h = CubicSplineInterpolation(list_x,list_y,2,1,0)
|
||||
print("二阶导数边界条件:")
|
||||
PrintResult(M,list_h,list_x,list_y)
|
||||
|
||||
M,list_h = CubicSplineInterpolation(list_x,list_y,1,1,0)
|
||||
print("一阶导数边界条件:")
|
||||
PrintResult(M,list_h,list_x,list_y)
|
||||
|
||||
|
||||
|
||||
|
||||
93
按方法整理/插值-牛顿前插-牛顿基本插值.py
Normal file
93
按方法整理/插值-牛顿前插-牛顿基本插值.py
Normal file
@@ -0,0 +1,93 @@
|
||||
import math
|
||||
|
||||
# 求差分表
|
||||
def GetDyList(list_y):
|
||||
result = []
|
||||
result.append(list_y)
|
||||
for i in range(len(list_y)-1,0,-1):
|
||||
tmp = []
|
||||
for j in range(i):
|
||||
tmp.append(result[len(list_y)-1-i][j+1] - result[len(list_y)-1-i][j])
|
||||
result.append(tmp)
|
||||
return result
|
||||
|
||||
# 牛顿前插余项计算
|
||||
def NewtonForwardRegression(x,n,list_x,FxDiff_n):
|
||||
h = list_x[1] - list_x[0]
|
||||
t = (x - list_x[0]) / h
|
||||
ks = max([abs(FxDiff_n(list_x[i],n)) for i in range(n)])
|
||||
result = 1
|
||||
for i in range(n):
|
||||
result *= (t-i)*h/(i+1)
|
||||
return result * ks
|
||||
|
||||
# 牛顿前插
|
||||
def NewtonForwardInterpolation(x,n,list_x,list_y,FxDiff_n):
|
||||
list_dyk = GetDyList(list_y)
|
||||
print("\n差分表")
|
||||
print("--------------------------------------------------")
|
||||
for i in range(len(list_dyk)):
|
||||
print(list_dyk[i])
|
||||
print("--------------------------------------------------")
|
||||
h = list_x[1] - list_x[0]
|
||||
t = (x - list_x[0]) / h
|
||||
result = list_y[0]
|
||||
mul = 1
|
||||
result = list_y[0]
|
||||
for i in range(1, n):
|
||||
mul *= ((t-i+1)/i)
|
||||
result += list_dyk[i][0] * mul
|
||||
r = abs(NewtonForwardRegression(x,n,list_x,FxDiff_n))
|
||||
return (result,r)
|
||||
|
||||
# 求差商表
|
||||
def GetDQyList(list_x,list_y):
|
||||
result = []
|
||||
result.append(list_y)
|
||||
for i in range(len(list_y)-1,0,-1):
|
||||
tmp = []
|
||||
for j in range(i):
|
||||
tmp.append((result[len(list_y)-1-i][j+1] - result[len(list_y)-1-i][j])/(list_x[j+len(list_y)-i] - list_x[j]))
|
||||
result.append(tmp)
|
||||
return result
|
||||
|
||||
|
||||
# 牛顿基本插值
|
||||
def NewtonBaseInterpolation(x,n,list_x,list_y):
|
||||
list_dqy = GetDQyList(list_x,list_y)
|
||||
print("\n差商表")
|
||||
print("--------------------------------------------------")
|
||||
for i in range(len(list_dqy)):
|
||||
print(list_dqy[i])
|
||||
print("--------------------------------------------------")
|
||||
result = list_dqy[0][0]
|
||||
mul = 1
|
||||
for i in range(1,n):
|
||||
mul *= (x - list_x[i-1])
|
||||
result += list_dqy[i][0] * mul
|
||||
return result
|
||||
|
||||
|
||||
|
||||
# 定义原函数和其导函数计算结果,用于计算牛顿前插的截断误差,如果不需要则不用管
|
||||
def FxDiff_n1(x,n):
|
||||
result = 0
|
||||
if n == 0:
|
||||
# 下面改成原函数 ############################################################
|
||||
result = math.exp(x)
|
||||
else:
|
||||
# 下面改成n阶导数 ##############################################################################
|
||||
result = math.exp(x)
|
||||
return result
|
||||
|
||||
|
||||
if __name__ == '__main__':
|
||||
##############################################################################################################
|
||||
list_x = [0.0,0.2,0.4,0.6,0.8] # 已给出的x数值,与y数值对应
|
||||
list_y = [1.0,1.2214,1.4918,1.8221,2.2255] # 已给出的y数值,与x数值对应
|
||||
x_to_predict = 0.12 # 要预测的x值
|
||||
# 记得改下面的点数(第二个参数),n是点数,阶数为n-1 ################################
|
||||
print("三点牛顿前插结果为%f, 截断误差%f" % NewtonForwardInterpolation(x_to_predict, 3, list_x, list_y,FxDiff_n1))
|
||||
print("四点牛顿前插结果为%f, 截断误差%f" % NewtonForwardInterpolation(x_to_predict, 4, list_x, list_y,FxDiff_n1))
|
||||
print("三点牛顿基本插值结果为%f" % NewtonBaseInterpolation(x_to_predict, 3, list_x, list_y))
|
||||
print("四点牛顿基本插值结果为%f" % NewtonBaseInterpolation(x_to_predict, 4, list_x, list_y))
|
||||
79
按方法整理/插值-线性-抛物线-拉格朗日多项式.py
Normal file
79
按方法整理/插值-线性-抛物线-拉格朗日多项式.py
Normal file
@@ -0,0 +1,79 @@
|
||||
import math
|
||||
|
||||
# 获取与待求x最接近的两个点
|
||||
def GetClosestTwo(x,list_x):
|
||||
for i in range(0, len(list_x)):
|
||||
if x < list_x[i]:
|
||||
return i-1, i
|
||||
return len(list_x)-2, len(list_x)-1
|
||||
|
||||
# 获取与待求x最接近的三个点
|
||||
def GetClosestThree(x,list_x):
|
||||
if x < list_x[1]:
|
||||
return 0, 1, 2
|
||||
for i in range(3, len(list_x)):
|
||||
if x < list_x[i]:
|
||||
return i-2, i-1, i
|
||||
return len(list_x)-3, len(list_x)-2, len(list_x)-1
|
||||
|
||||
# 线性插值余项计算
|
||||
def LinearRegression(x,list_x,FxDiff_n):
|
||||
i, j = GetClosestTwo(x,list_x)
|
||||
ks = max([abs(FxDiff_n(list_x[i],2)), abs(FxDiff_n(list_x[j],2))])
|
||||
omg = (x-list_x[i])*(x-list_x[j])
|
||||
return abs(ks*omg/2)
|
||||
|
||||
# 抛物线插值余项计算
|
||||
def ParabolaRegression(x,list_x,FxDiff_n):
|
||||
i, j, k = GetClosestThree(x,list_x)
|
||||
ks = max([abs(FxDiff_n(list_x[i],3)), abs(FxDiff_n(list_x[j],3)), abs(FxDiff_n(list_x[k],3))])
|
||||
omg = (x-list_x[i])*(x-list_x[j])*(x-list_x[k])
|
||||
return abs(ks*omg/6)
|
||||
|
||||
# 线性插值
|
||||
def LinearInterpolation(x,list_x,list_y,FxDiff_n):
|
||||
i, j = GetClosestTwo(x,list_x)
|
||||
result = list_y[i] + (x - list_x[i]) * (list_y[j] - list_y[i]) / (list_x[j] - list_x[i])
|
||||
r = LinearRegression(x,list_x,FxDiff_n)
|
||||
return (result,r)
|
||||
|
||||
# 抛物线插值
|
||||
def ParabolaInterpolation(x,list_x,list_y,FxDiff_n):
|
||||
i, j, k = GetClosestThree(x,list_x)
|
||||
result = list_y[i] * (x - list_x[j]) * (x - list_x[k]) / (list_x[i] - list_x[j]) / (list_x[i] - list_x[k])
|
||||
result += list_y[j] * (x - list_x[i]) * (x - list_x[k]) / (list_x[j] - list_x[i]) / (list_x[j] - list_x[k])
|
||||
result += list_y[k] * (x - list_x[i]) * (x - list_x[j]) / (list_x[k] - list_x[i]) / (list_x[k] - list_x[j])
|
||||
r = ParabolaRegression(x,list_x,FxDiff_n)
|
||||
return (result,r)
|
||||
|
||||
# 拉格朗日插值
|
||||
def LagrangeInterpolation(x,list_x,list_y):
|
||||
result = 0
|
||||
for i in range(0, len(list_x)):
|
||||
temp = 1
|
||||
for j in range(0, len(list_x)):
|
||||
if i != j:
|
||||
temp *= (x - list_x[j]) / (list_x[i] - list_x[j])
|
||||
result += temp * list_y[i]
|
||||
return result
|
||||
|
||||
# 定义原函数和其导函数计算结果,用于计算插值的截断误差,如果不需要则不用管
|
||||
def FxDiff_n1(x,n):
|
||||
result = 0
|
||||
if n == 0:
|
||||
# 下面改成原函数 ############################################################
|
||||
result = math.log(x)
|
||||
else:
|
||||
# 下面改成n阶导数 ##############################################################################
|
||||
result = (-1)**(n+1) * math.factorial(n-1) / (x**n)
|
||||
return result
|
||||
|
||||
if __name__ == "__main__":
|
||||
##############################################################################
|
||||
list_x = [10,11,12,13] # 已给出的x数值,与y数值对应
|
||||
list_y = [2.3026,2.3979,2.4849,2.5649] # 已给出的y数值,与x数值对应
|
||||
x_to_predict = 11.75 # 要预测的x值
|
||||
print("线性插值结果为%f, 截断误差%f" % LinearInterpolation(x_to_predict,list_x,list_y,FxDiff_n1))
|
||||
print("抛物线插值结果为%f, 截断误差%f" % ParabolaInterpolation(x_to_predict,list_x,list_y,FxDiff_n1))
|
||||
|
||||
# print(LagrangeInterpolation(x_to_predict,list_x,list_y))
|
||||
38
按方法整理/数值积分-复合梯形-复合辛普生法.py
Normal file
38
按方法整理/数值积分-复合梯形-复合辛普生法.py
Normal file
@@ -0,0 +1,38 @@
|
||||
|
||||
|
||||
# 复合Newton-Cotes公式 复合牛顿-柯特斯公式
|
||||
# n等分参数,x1到x2的区间,type=1表示梯形法,type=2表示辛普生法
|
||||
def CompositeNewtonCotes(x_start,x_end,fx,n, type):
|
||||
if type == 1:
|
||||
h = (x_end - x_start) / n
|
||||
result = 0
|
||||
for i in range(n):
|
||||
result += (fx(x_start + i * h) + fx(x_start + (i + 1) * h))
|
||||
result *= (h / 2)
|
||||
return result
|
||||
elif type == 2:
|
||||
h = (x_end - x_start) / n
|
||||
result = -fx(x_start) + fx(x_end)
|
||||
for i in range(n):
|
||||
result += (4 * fx(x_start + (i + 0.5) * h) + 2 * fx(x_start + i * h))
|
||||
result *= (h / 6)
|
||||
return result
|
||||
|
||||
|
||||
# 积分原函数 ##############################################################
|
||||
def fx(x):
|
||||
if x == 0:
|
||||
x = 1e-10 # Avoid division by zero #如果x能为0,注释掉这行##############
|
||||
pass
|
||||
return x/(4+x**2) #把函数改成题干的形式###################
|
||||
|
||||
if __name__ == "__main__":
|
||||
##############################################################################################################
|
||||
x_start = 3.0 # 积分下限
|
||||
x_end = 6.0 # 积分上限
|
||||
# 复合梯形公式,点数为n+1
|
||||
print("复合梯形公式\n", CompositeNewtonCotes(x_start,x_end,fx,8, 1)) #8等分,1代表是梯形公式####################
|
||||
# 复合辛普生公式,点数为2n+1
|
||||
print("复合辛普生公式\n", CompositeNewtonCotes(x_start,x_end,fx,4, 2)) #4等分,2代表是辛普生公式###############
|
||||
|
||||
|
||||
38
按方法整理/数值积分-逐次分半梯形递推公式.py
Normal file
38
按方法整理/数值积分-逐次分半梯形递推公式.py
Normal file
@@ -0,0 +1,38 @@
|
||||
import math
|
||||
|
||||
# 逐次分半梯形递推公式
|
||||
def SplitTrapezoidal(a,b,fx,err):
|
||||
count = 1
|
||||
t1 = (b-a)*(fx(a)+fx(b))/2
|
||||
print(f"t{count}={t1}")
|
||||
k = 1
|
||||
while True:
|
||||
tmp = 0
|
||||
for i in range(1, 2**(k-1)+1):
|
||||
tmp += fx(a + (b-a)*(2*i-1)/(2**k))
|
||||
t2 = t1/2+(b-a)*tmp/(2**k)
|
||||
count *= 2
|
||||
print(f"t{count}={t2}")
|
||||
if abs(t2-t1) < err:
|
||||
break
|
||||
t1 = t2
|
||||
k += 1
|
||||
return t2,k
|
||||
|
||||
|
||||
# 积分原函数 ##############################################################
|
||||
def fx(x):
|
||||
if x == 0:
|
||||
x = 1e-10 # Avoid division by zero #如果x能为0,注释掉这行##############
|
||||
pass
|
||||
return 1/x #把函数改成题干的形式###################
|
||||
|
||||
|
||||
if __name__ == "__main__":
|
||||
##############################################################################################################
|
||||
x_start = 1 # 积分下限
|
||||
x_end = 3 # 积分上限
|
||||
err = 1e-2 # 精度要求 P106
|
||||
|
||||
result,k = SplitTrapezoidal(x_start, x_end, fx, err)
|
||||
print(f"Result: {result},k={k}")
|
||||
71
按方法整理/数值积分-龙贝格算法.py
Normal file
71
按方法整理/数值积分-龙贝格算法.py
Normal file
@@ -0,0 +1,71 @@
|
||||
import math
|
||||
|
||||
# 龙贝格方法 积分
|
||||
def Romberg(a, b, fx, err):
|
||||
table = [[],[],[],[]]
|
||||
t00 = (b-a)*(fx(a)+fx(b))/2
|
||||
table[0].append(t00)
|
||||
print(f"t0(0)={t00}")
|
||||
t01 = t10 = t11 = t20 = t21 = t30 = t31 = 0
|
||||
k = 1
|
||||
while True:
|
||||
tmp = 0
|
||||
for i in range(1, 2**(k-1)+1):
|
||||
tmp += fx(a + (b-a)*(2*i-1)/(2**k))
|
||||
t01 = t00/2+(b-a)*tmp/(2**k)
|
||||
print(f"t0({k})={t01}")
|
||||
table[0].append(t01)
|
||||
|
||||
if k>1:
|
||||
t11 = (4*t01-t00)/3
|
||||
print(f"t1({k-1})={t11}")
|
||||
table[1].append(t11)
|
||||
if k>2:
|
||||
t21 = (16*t11-t10)/15
|
||||
print(f"t2({k-2})={t21}")
|
||||
table[2].append(t21)
|
||||
if k>3:
|
||||
t31 = (64*t21-t20)/63
|
||||
print(f"t3({k-3})={t31}")
|
||||
table[3].append(t31)
|
||||
if abs(t31-t30) < err:
|
||||
break
|
||||
t30 = t31
|
||||
else:
|
||||
t30 = (64*t21-t20)/63
|
||||
print(f"t3(0)={t30}")
|
||||
table[3].append(t30)
|
||||
t20 = t21
|
||||
else:
|
||||
t20 = (16*t11-t10)/15
|
||||
print(f"t2(0)={t20}")
|
||||
table[2].append(t20)
|
||||
t10 = t11
|
||||
else:
|
||||
t10 = (4*t01-t00)/3
|
||||
print(f"t1(0)={t10}")
|
||||
table[1].append(t10)
|
||||
t00 = t01
|
||||
k += 1
|
||||
print("Romberg table:")
|
||||
for i in range(len(table)):
|
||||
print(f"t{i}: {table[i]}")
|
||||
return t31, k
|
||||
|
||||
|
||||
# 积分原函数 ##############################################################
|
||||
def fx(x):
|
||||
if x == 0:
|
||||
x = 1e-10 # Avoid division by zero #如果x能为0,注释掉这行##############
|
||||
pass
|
||||
return math.sin(x)/x #把函数改成题干的形式###################
|
||||
|
||||
|
||||
if __name__ == "__main__":
|
||||
##############################################################################################################
|
||||
x_start = 0 # 积分下限
|
||||
x_end = 1 # 积分上限
|
||||
err = 0.5e-6 # 精度要求 P113
|
||||
|
||||
result, k = Romberg(x_start, x_end, fx, err)
|
||||
print(f"Result: {result}, k={k}")
|
||||
89
按方法整理/矩阵-列主元高斯消元法.py
Normal file
89
按方法整理/矩阵-列主元高斯消元法.py
Normal file
@@ -0,0 +1,89 @@
|
||||
import math
|
||||
|
||||
# 列主元高斯消元法
|
||||
def SovleRowMain(A,b):
|
||||
ks = 0.00000001
|
||||
n = len(A)
|
||||
if len(A[0]) != n:
|
||||
print("A要为方阵")
|
||||
return None,None,None,None
|
||||
if len(b) != n:
|
||||
print("b与A的行数不匹配")
|
||||
return None,None,None,None
|
||||
p = list(range(n))
|
||||
for i in range(n):
|
||||
row_max = abs(A[i][i])
|
||||
row_max_index = i
|
||||
for j in range(i + 1, n):
|
||||
if abs(A[j][i]) > row_max:
|
||||
row_max = abs(A[j][i])
|
||||
row_max_index = j
|
||||
A[i], A[row_max_index] = A[row_max_index], A[i]
|
||||
b[i], b[row_max_index] = b[row_max_index], b[i]
|
||||
p[i], p[row_max_index] = p[row_max_index], p[i]
|
||||
|
||||
if abs(A[i][i]) < ks:
|
||||
print("A矩阵奇异,无法进行高斯消元")
|
||||
return None,None,None,None
|
||||
for j in range(i + 1, n):
|
||||
m = A[j][i] / A[i][i]
|
||||
A[j][i] = m
|
||||
for k in range(i + 1, n):
|
||||
A[j][k] -= m * A[i][k]
|
||||
b[j] -= m * b[i]
|
||||
|
||||
if abs(A[n - 1][n - 1]) < ks:
|
||||
print("A矩阵奇异,无法进行高斯消元")
|
||||
return None,None,None,None
|
||||
|
||||
# 回代求解
|
||||
b[n - 1] /= A[n - 1][n - 1]
|
||||
for i in range(n - 2, -1, -1):
|
||||
for j in range(i + 1, n):
|
||||
b[i] -= A[i][j] * b[j]
|
||||
b[i] /= A[i][i]
|
||||
|
||||
# 得到L,U和P矩阵
|
||||
L = [[0 for i in range(n)] for j in range(n)]
|
||||
U = [[0 for i in range(n)] for j in range(n)]
|
||||
P = [[0 for i in range(n)] for j in range(n)]
|
||||
for i in range(n):
|
||||
for j in range(n):
|
||||
if i == j:
|
||||
L[i][j] = 1
|
||||
U[i][j] = A[i][j]
|
||||
elif i < j:
|
||||
U[i][j] = A[i][j]
|
||||
else:
|
||||
L[i][j] = A[i][j]
|
||||
|
||||
P[i][p[i]] = 1
|
||||
return P,L,U,b
|
||||
#打印矩阵
|
||||
def prettyPrintMatrix(matrix):
|
||||
for row in matrix:
|
||||
print(row)
|
||||
|
||||
|
||||
if __name__ == "__main__":
|
||||
##########################################################################
|
||||
#把矩阵A和b改成题干要求的#####################################
|
||||
A = [
|
||||
[0, 3, 4],
|
||||
[1, -1, 1],
|
||||
[2, 1, 2]
|
||||
]
|
||||
|
||||
b = [1, 2, 3]
|
||||
|
||||
P,L,U,x = SovleRowMain(A, b)
|
||||
print("P:")
|
||||
prettyPrintMatrix(P)
|
||||
print("L:")
|
||||
prettyPrintMatrix(L)
|
||||
print("U:")
|
||||
prettyPrintMatrix(U)
|
||||
print("x:")
|
||||
print(x)
|
||||
|
||||
|
||||
29
按方法整理/非线性方程-二分法.py
Normal file
29
按方法整理/非线性方程-二分法.py
Normal file
@@ -0,0 +1,29 @@
|
||||
import math
|
||||
|
||||
# 二分法求解方程的根
|
||||
def SolveByDivTwo(x1,x2,fx,err):
|
||||
count = 1
|
||||
|
||||
while abs(x2-x1) >= err:
|
||||
x = (x1+x2)/2
|
||||
print(f"k={count},a{count}={x1},b{count}={x2},x{count}={x},fx(x)={fx(x)}")
|
||||
if fx(x) * fx(x1) < 0:
|
||||
x2 = x
|
||||
else:
|
||||
x1 = x
|
||||
count += 1
|
||||
|
||||
return (x1+x2)/2
|
||||
|
||||
|
||||
# 原函数换成题干的 #############################
|
||||
def fx(x):
|
||||
return x**4-3*x+1
|
||||
|
||||
if __name__ == "__main__":
|
||||
##############################################################################################################
|
||||
x1 = 0.3 # x下限范围
|
||||
x2 = 0.4 # x上限范围
|
||||
err = 0.5e-5 # 精度要求 P125
|
||||
root = SolveByDivTwo(x1, x2,fx,err)
|
||||
print(f"Root: {root}")
|
||||
65
按方法整理/非线性方程-抛物线法.py
Normal file
65
按方法整理/非线性方程-抛物线法.py
Normal file
@@ -0,0 +1,65 @@
|
||||
import math
|
||||
|
||||
|
||||
#抛物线法解方程
|
||||
def MullerSolve(fx,x0,x1,x2,err1,err2,N):
|
||||
count = 0
|
||||
f0 = fx(x0)
|
||||
f1 = fx(x1)
|
||||
f2 = fx(x2)
|
||||
q = (x2 - x1) / (x1 - x0)
|
||||
p = 0
|
||||
a = 0
|
||||
b = 0
|
||||
c = 0
|
||||
while True:
|
||||
p = (x2 - x0) / (x1 - x0)
|
||||
|
||||
a = q**2 * f0 - q*p*f1 + q*f2
|
||||
b = q**2 *f0 - p**2 *f1 + (p + q)*f2
|
||||
c = p*f2
|
||||
h1 = 0
|
||||
if b < 0:
|
||||
h1 = -2 * c / (b - (b**2 - 4*a*c)**0.5)
|
||||
else:
|
||||
h1 = -2 * c / (b + (b**2 - 4*a*c)**0.5)
|
||||
x3 = x2 + h1 * (x2 - x1)
|
||||
f3 = fx(x3)
|
||||
|
||||
print(f"k={count}: x{count}={x0:.5}, f(x{count})={f0:.5}; x{count+1}={x1:.5}, f(x{count+1})={f1:.5}; x{count+2}={x2:.5}, f(x{count+2})={f2:.5}; x{count+3}={x3:.5}, f(x{count+3})={f3:.5}")
|
||||
print(f"p={p:.5}, q={q:.5}, a={a:.5}, b={b:.5}, c={c:.5}, h={h1:.5}")
|
||||
|
||||
k = err1 + 1
|
||||
if abs(f3) < 1:
|
||||
k = abs(x3 - x2)
|
||||
else:
|
||||
k = abs(x3 - x2) / abs(f3)
|
||||
|
||||
if abs(f3) < err2 or k < err1:
|
||||
return x3, 1
|
||||
count += 1
|
||||
if count > N:
|
||||
return None, 0
|
||||
x0 = x1
|
||||
x1 = x2
|
||||
x2 = x3
|
||||
f0 = f1
|
||||
f1 = f2
|
||||
f2 = f3
|
||||
q = h1
|
||||
|
||||
|
||||
if __name__ == "__main__":
|
||||
err1 = 1e-5 # 精度要求 P152
|
||||
err2 = 1e-5 # 精度要求 P152
|
||||
N = 100 # 最大迭代次数
|
||||
x0 = 0.3 # 初始值1
|
||||
x1 = 0.5 # 初始值2
|
||||
x2 = 0.4 # 初始值3
|
||||
fx = lambda x: 8*x**4 - 8*x**2 + 1 #原函数
|
||||
|
||||
result, status = MullerSolve(fx, x0, x1, x2, err1, err2, N)
|
||||
if status == 1:
|
||||
print(f"fx收敛 解为: {result}")
|
||||
else:
|
||||
print("fx不收敛")
|
||||
38
按方法整理/非线性方程-正割法.py
Normal file
38
按方法整理/非线性方程-正割法.py
Normal file
@@ -0,0 +1,38 @@
|
||||
import math
|
||||
|
||||
|
||||
#正割法计算方程
|
||||
def SecantSolve(fx, x0, x1, err=1e-10, N0=100):
|
||||
count = 0
|
||||
print(f"k={count}: x{count}={x0}, f(x{count})={fx(x0)}")
|
||||
count += 1
|
||||
print(f"k={count}: x{count}={x1}, f(x{count})={fx(x1)}")
|
||||
count += 1
|
||||
while abs(x1 - x0) > err or abs(fx(x1)) > err:
|
||||
if fx(x1) == fx(x0):
|
||||
return None,0
|
||||
x2 = x1 - fx(x1) * (x1 - x0) / (fx(x1) - fx(x0))
|
||||
print(f"k={count}: x{count}={x2}, f(x{count})={fx(x2)}")
|
||||
count += 1
|
||||
if count > N0:
|
||||
return None,-1
|
||||
x0 = x1
|
||||
x1 = x2
|
||||
return x2,1
|
||||
|
||||
|
||||
if __name__ == "__main__":
|
||||
##############################################################################################################
|
||||
err = 1e-5 # 根的误差限 P148
|
||||
N0 = 100 # 最大迭代次数
|
||||
x0 = 0.3 # 初始值1
|
||||
x1 = 0.4 # 初始值2
|
||||
fx = lambda x: x**4 - 3*x + 1 #原函数
|
||||
|
||||
result, status = SecantSolve(fx, x0, x1, err, N0)
|
||||
if status == 1:
|
||||
print(f"fx收敛 解为: {result}")
|
||||
elif status == -1:
|
||||
print("fx不收敛")
|
||||
else:
|
||||
print("分母为0,无法收敛")
|
||||
50
按方法整理/非线性方程-牛顿下山法.py
Normal file
50
按方法整理/非线性方程-牛顿下山法.py
Normal file
@@ -0,0 +1,50 @@
|
||||
import math
|
||||
|
||||
def NewtonDownHillSolve(fx, dfx, x0, err1,err2, N0,min_t):
|
||||
count = 0
|
||||
print(f"k={count}, x0={x0}")
|
||||
x1 = x0 + 1 + err1
|
||||
while abs(x1 - x0) > err1 or abs(fx(x1)) > err2:
|
||||
t = 1
|
||||
if abs(dfx(x1)) < 1e-10:
|
||||
print("导数为0,无法下山")
|
||||
return None, 0
|
||||
print(f"当前点: x0={x0}")
|
||||
while t >= min_t:
|
||||
x1 = x0 - t * fx(x0) / dfx(x0)
|
||||
print(f"下山: t={t}, x1={x1}, abs(fx(x1))={abs(fx(x1))}, abs(fx(x0))={abs(fx(x0))}")
|
||||
if abs(fx(x1)) < abs(fx(x0)):
|
||||
break
|
||||
t *= 0.5
|
||||
if t < min_t:
|
||||
print("达到最小t,下山失败")
|
||||
return None, -2
|
||||
# x1 = x0 - fx(x0) / dfx(x0)
|
||||
count += 1
|
||||
print(f"k={count}, x{count}={x1},x1-x0={abs(x1-x0)}")
|
||||
if count > N0:
|
||||
return None, -1
|
||||
x0 = x1
|
||||
print(f"收敛: x1={x1}, fx(x1)={fx(x1)}")
|
||||
return x1, 1
|
||||
|
||||
|
||||
if __name__ == "__main__":
|
||||
##############################################################################################################
|
||||
err1 = 1e-5 # 根的误差限 见P147
|
||||
err2 = 1e-5 # 残量精度 见P147
|
||||
N0 = 100 # 最大迭代次数
|
||||
min_t = 1e-10 # 最小t值
|
||||
x0 = 0.6 # 初始值
|
||||
fx = lambda x: x**3 - x - 1 # 原函数
|
||||
dfx = lambda x: 3*x**2 - 1 # 导函数
|
||||
|
||||
result, status = NewtonDownHillSolve(fx, dfx, x0, err1, err2, N0, min_t)
|
||||
if status == 1:
|
||||
print(f"收敛 解为: {result}")
|
||||
elif status == -1:
|
||||
print("不收敛")
|
||||
elif status == -2:
|
||||
print("下山失败")
|
||||
else:
|
||||
print("导数为0,无法收敛")
|
||||
50
按方法整理/非线性方程-牛顿法.py
Normal file
50
按方法整理/非线性方程-牛顿法.py
Normal file
@@ -0,0 +1,50 @@
|
||||
import math
|
||||
|
||||
|
||||
# 牛顿方法求解方程
|
||||
def NewtonSolve(fx, dfx, x0, err, N0):
|
||||
count = 0
|
||||
print(f"k={count}, x0={x0}")
|
||||
x1 = x0 + 1 + err
|
||||
while abs(x1 - x0) > err or abs(fx(x1)) > err: # 添加条件修正根误差太大的问题
|
||||
if abs(dfx(x1)) < 1e-10:
|
||||
return None, 0
|
||||
x1 = x0 - fx(x0) / dfx(x0)
|
||||
count += 1
|
||||
print(f"k={count}, x{count}={x1},x1-x0={abs(x1-x0)}")
|
||||
if count > N0:
|
||||
return None, -1
|
||||
x0 = x1
|
||||
return x1, 1
|
||||
|
||||
# 查找根区间
|
||||
def FindRootZone(fx,start,stop,step):
|
||||
x = start
|
||||
while x < stop:
|
||||
if fx(x) * fx(x+step) < 0:
|
||||
return x
|
||||
x += step
|
||||
return None
|
||||
|
||||
# 定义原函数 ###############################
|
||||
def fx(x):
|
||||
return x**2 + 10*math.cos(x)
|
||||
|
||||
# 定义其导函数 ###############################
|
||||
def dfx(x):
|
||||
return 2*x - 10*math.sin(x)
|
||||
|
||||
if __name__ == "__main__":
|
||||
##############################################################################################################
|
||||
err = 1e-5 # 根的误差限 见P141
|
||||
N0 = 100 # 最大迭代次数
|
||||
x0 = 1.6 # 可以指定初始值
|
||||
# x0 = FindRootZone(fx, 0, 2, 0.1) # 也可以用找根函数给定范围找根的缩小范围
|
||||
|
||||
result,status = NewtonSolve(fx, dfx, x0, err,N0)
|
||||
if status == 1:
|
||||
print(f"fx收敛 解为: {result}")
|
||||
elif status == -1:
|
||||
print("fx不收敛")
|
||||
else:
|
||||
print("fx导数为0,无法收敛")
|
||||
40
按方法整理/非线性方程-画图找零点.py
Normal file
40
按方法整理/非线性方程-画图找零点.py
Normal file
@@ -0,0 +1,40 @@
|
||||
import math
|
||||
import matplotlib.pyplot as plt
|
||||
|
||||
|
||||
# 绘制函数图像 并标记可能的零点
|
||||
def DrawGraph(a, b, stepper):
|
||||
x = [a + (b-a)*i*stepper for i in range(int(1/stepper+1))]
|
||||
y = [fx(i) for i in x]
|
||||
plt.xlim(a-abs(b-a)*0.1, b+abs(b-a)*0.1)
|
||||
plt.plot(x, y)
|
||||
plt.axhline(0, color='black', lw=0.5, ls='-')
|
||||
plt.axvline(a, color='red', lw=0.5, ls='--')
|
||||
plt.axvline(b, color='red', lw=0.5, ls='--')
|
||||
plt.text(a, y[0], f'({a:.5f},{y[0]:.5f})', fontsize=8, ha='left')
|
||||
plt.text(b, y[-1], f'({b:.5f},{y[-1]:.5f})', fontsize=8, ha='right')
|
||||
for i in range(len(x)-1):
|
||||
if y[i] * y[i+1] < 0:
|
||||
print(f"可能存在零点: ({x[i]:.5f},{y[i]:.5f})和({x[i+1]:.5f},{y[i+1]:.5f})之间")
|
||||
plt.plot((x[i]+x[i+1])/2, (y[i]+y[i+1])/2, 'ro', markersize=3)
|
||||
plt.title("Graph of f(x)")
|
||||
plt.xlabel("x")
|
||||
plt.ylabel("f(x)")
|
||||
plt.show()
|
||||
return x, y
|
||||
|
||||
|
||||
|
||||
# 把原函数换成题干的形式,自己注意定义域########################
|
||||
def fx(x):
|
||||
return math.exp(x)-math.sin(x)
|
||||
|
||||
|
||||
if __name__ == "__main__":
|
||||
##############################################################################################################
|
||||
a = -2*math.pi # 左边界
|
||||
b = math.pi # 右边界
|
||||
step = 0.00001 # 步长
|
||||
print(f"边界点: {a}, {b}")
|
||||
print(f"步长: {step}")
|
||||
x, y = DrawGraph(a, b, step)
|
||||
46
按方法整理/非线性方程-迭代法.py
Normal file
46
按方法整理/非线性方程-迭代法.py
Normal file
@@ -0,0 +1,46 @@
|
||||
def fd1(x):
|
||||
return 1+1/x**2
|
||||
|
||||
def fd2(x):
|
||||
return 1/(x-1)**0.5
|
||||
|
||||
# 迭代法求解方程
|
||||
def Renew(x,fd,err):
|
||||
count=0
|
||||
i = 0
|
||||
try:
|
||||
while True:
|
||||
xk = fd(x)
|
||||
print(f"当前迭代值: {xk}, 上一次迭代值: {x}, 误差: {abs(xk-x)}")
|
||||
if abs(i) < (xk-x):
|
||||
count += 1
|
||||
else:
|
||||
count = 0
|
||||
if count > 10:
|
||||
print("不收敛")
|
||||
break
|
||||
if abs(xk-x) < err:
|
||||
return xk
|
||||
i = xk-x
|
||||
x = xk
|
||||
except Exception as e:
|
||||
print(f"发生错误: {e}")
|
||||
return None
|
||||
return None
|
||||
|
||||
|
||||
# 定义迭代公式 x = fd(x) ###############################
|
||||
def fd(x):
|
||||
return 1+1/x**2
|
||||
|
||||
if __name__ == "__main__":
|
||||
##############################################################################################################
|
||||
x0 = 1.5 # 初始值
|
||||
err = 1e-5 # 精度要求 P136
|
||||
|
||||
result = Renew(x0, fd, err)
|
||||
if result is not None:
|
||||
print(f"收敛 解为: {result:.5f}")
|
||||
else:
|
||||
print("不收敛")
|
||||
|
||||
Reference in New Issue
Block a user